The following disclosure relates to mechanical equipment used in oil field operations, and in particular to high-capacity clamps for transmitting rotational torque to drill pipe or casing. In one embodiment, a powered clamp transmits rotational torque from the rotary of a snubbing jack or rig assist unit to drill pipe or casing during continuous rotation operations such as milling or drilling. The power for the clamp may be supplied by hydraulic, pneumatic or electric actuators.
During the operation of a snubbing jack or rig assist unit, it is sometimes necessary to use the unit's powered rotary to drill or mill out material down-hole. The slip bowls that are used to hold the drill pipe (i.e., in the vertical direction) are not rated to handle torque. Because of this, a milling clamp is typically employed to transmit the torque from the rotary to the drill pipe/casing.
The most prevalent type of milling clamp currently used in the oil field industry today is a manual milling clamp that consists of a collar with set screws or T-bolts that are tightened against the pipe in order to transmit torque. Using such manual milling clamps may be labor-intensive, time consuming and/or inconvenient. A need therefore exists, for a milling clamp that is more convenient and less labor-intensive and time consuming to use.
In one aspect thereof, a powered milling clamp comprises an outer housing, an inner housing, industry standard back-up power tong inserts for gripping pipe, tangentially oriented and radially spaced linear actuators (hydraulic, pneumatic, or electric), and tapered inner housing support rollers. The outer housing is fixed to, and rotates with, the rotary. The inner housing rides on radially spaced tapered rollers. The linear actuators couple the outer and inner housings and rotate the inner housing with respect to the outer housing. The carriers are held tangentially relative to the outer housing by locating blocks or tracks. There is a pin on each carrier that rides in an associated slot in the inner housing. As the inner housing is rotated, the slots drive the carriers and pipe inserts radially into contact with the drill pipe/casing. Additional force from the linear actuators creates a substantial clamp load on the drill pipe. This clamp load transmits the torque from the rotary to the drill pipe/casing. The powered milling clamp can be sized according to the customer's specification to accommodate multiple drill pipe/casing diameters and torque ratings. The powered milling clamp is more efficient, safer and more reliable than the existing manual milling clamps.
In another aspect, a powered clamp for transmitting rotational torque from a rotary drive to a drill pipe comprises an outer housing adapted for releasable attachment to the rotary drive to receive torque from the rotary drive, the outer housing having an upper plate and a lower plate connected to a plurality of carrier guides disposed therebetween. The upper plate and lower plate define a central passage along a clamp centerline axis, and the plurality of carrier guides define a plurality of slots between one another, the slots being radially oriented with respect to the clamp centerline axis. The clamp further comprises an inner housing having a top plate and a bottom plate connected to a plurality of spacers disposed therebetween and defining a central passage along the clamp centerline axis. The inner housing is disposed between the upper and lower plates of the outer housing and is rotatably connected to the outer housing to allow rotation of the inner housing about the clamp centerline axis relative to the outer housing. At least one of the top and bottom plates defines a plurality of actuator slots therein, the actuator slots having a generally spiral configuration relative to the clamp centerline axis. A plurality of carriers are slidably disposed between the top and bottom plates of the inner housing and in the slots between the carrier guides, each carrier having a carrier pin extending into one of the actuator slots of the inner housing. The clamp further comprises at least one powered linear actuator oriented substantially tangential to the clamp centerline axis and connected at a first end to the outer housing and at a second end to the inner housing. Selective extension and retraction of the linear actuator causes the inner housing to rotate about the clamp centerline axis relative to the outer housing, which rotation in turn causes the carriers to move radially inward and outward as the carrier pin travels along the actuator slot so as to selectively grip and release the drill pipe disposed in the central passage along the clamp centerline axis.
In one embodiment, the powered linear actuator(s) are hydraulically powered.
In another embodiment, the powered linear actuator(s) are pneumatically powered.
In still another embodiment, the powered linear actuator(s) are electrically powered.
In a further embodiment, the outer housing further comprises a plurality of rollers disposed on axles extending between the upper plate and the lower plate parallel to the clamp centerline axis for radially supporting the inner housing.
In yet another embodiment, the rollers of the outer housing are straight sided rollers.
In another embodiment, the rollers of the outer housing are center tapered rollers.
In still another embodiment, the rollers of the outer housing are configured in a plurality of groups of rollers, the spacing between the adjacent axles of the rollers within a group being less that the spacing between the adjacent axles of rollers in different groups, and the number of groups of rollers is same as the number of carriers.
In a further embodiment, each respective group of the plurality of groups of rollers is disposed on the outer housing radially outwardly adjacent to a respective actuator slot on the inner housing and radially aligned with a respective one of the carriers.
In yet another embodiment, a wedge angle is defined at each point along each of the actuation slots from a beginning point at the OPEN end of the actuation slot to an end point at the CLOSE end of the actuation slot, the wedge angle at a particular point being formed between the direction of the centerline of the actuation slot at the particular point and the direction of a tangent line relative to the clamp centerline axis at the particular point. The wedge angle for the beginning point of the actuation slot is greater than the wedge angle for the end point of the actuation slot.
In another embodiment, the wedge angle of the actuation slots of the inner housing in at least the final 50% of the length of the actuation slot is relatively constant.
In still another embodiment, the wedge angle of the actuation slots of the inner housing in at least the final 50% of the length of the actuation slot is within the range from 4.25° to 4.75°.
In yet another embodiment, the wedge angle of the actuation slots of the inner housing in at least the final 40% of the length of the actuation slot is about 4.5°.
In yet another aspect, a powered clamp for transmitting rotational torque to a drill pipe comprises an outer housing connected to a plurality of carrier guides, the outer housing defining a central passage along a clamp centerline axis, and the plurality of carrier guides defining a plurality of slots between one another, the slots being radially oriented with respect to the clamp centerline axis. The powered clamp further comprises an inner housing defining a central passage along the clamp centerline axis. The inner housing is rotatably connected to the outer housing to allow rotation of the inner housing about the clamp centerline axis relative to the outer housing. The inner housing defines a plurality of actuator slots therein, and a plurality of carriers are slidably disposed in the slots between the carrier guides, each carrier having a carrier pin extending into one of the actuator slots of the inner housing. The powered clamp further comprises at least one powered linear actuator oriented substantially tangential to the clamp centerline axis and connected at a first end to the outer housing and at a second end to the inner housing. Selective extension and retraction of the linear actuator causes the inner housing to rotate about the clamp centerline axis relative to the outer housing, which rotation in turn causes the carriers to move radially inward and outward as the carrier pin travels along the actuator slot so as to selectively grip and release the drill pipe disposed in the central passage along the clamp centerline axis.
In one embodiment, a wedge angle is defined at each point along each of the actuation slots from a beginning point of the actuation slot to an end point of the actuation slot, the wedge angle at a particular point being formed between the direction of the centerline of the actuation slot at the particular point and the direction of a tangent line relative to the clamp centerline axis at the particular point, and the wedge angle for the beginning point of the actuation slot is greater than the wedge angle for the end point of the actuation slot.
In another embodiment, the wedge angle of the actuation slots of the inner housing in at least the final 50% of the length of the actuation slot is relatively constant.
In still another embodiment, the wedge angle of the actuation slots of the inner housing in at least the final 50% of the length of the actuation slot is within the range from 4.25 degrees to 4.75 degrees.
For a more complete understanding, reference is now made to the following description taken in conjunction with the accompanying drawings in which:
Referring first to
As best seen in
Referring now also to
As best seen in
The linear actuators 114 are generally tangentially oriented (relative to the clamp centerline axis 109) and radially spaced apart from one another. Each linear actuator 114 has an outer end 126 connected to the outer housing 102 and an inner end 128 connected to the inner housing 104. As previously described, as the actuators 114 are selectively extended and retracted, the inner housing 104 rotates back and forth about the centerline axis 109 relative to the outer housing 102.
A plurality of rollers 116 may be provided on the outer housing 102 to rotatably support the inner housing 114. The rollers 116 may be mounted on axles 117 extending between the upper plate 118 and the lower plate 120 and oriented parallel to the clamp centerline axis 109. In some embodiments, the rollers 116 may be evenly spaced around the periphery of the outer housing 102, whereas in other embodiments, the rollers may be positioned in localized groups of multiple rollers, with the groups being evenly spaced around the periphery of the outer housing (even though the rollers themselves are not evenly spaced). In still other embodiments, the rollers 116 and/or groups 119 may be unevenly spaced. A group of rollers may be considered a subset of the plurality of rollers 116 wherein the spacing between the adjacent axles 117 within the subset is less that the spacing between the axles of the outermost rollers in that subset and the nearest axles of the adjacent subset(s). Arranging the rollers 116 into groups 119 allows the support provided by the rollers to be concentrated in the areas where such support is most needed. For example, in the illustrated embodiment of
In the embodiment illustrated in
In an alternative embodiment illustrated in
Referring still to
Referring again to
Referring again to
As best seen in
As best seen in
In certain preferred embodiments, the wedge angle θW in the initial portion of the actuation slot 138 (i.e., the portion closest to the OPEN end 140), is greater than the wedge angle θW in the final portion (i.e., the portion closest to the CLOSE end 142), thereby providing relatively fast movement of the grippers/carriers 106 during the initial portion of the closing stroke and relatively slower movement during the final portion of the closing stroke. In other preferred embodiments, the wedge angle θW in at least the final 50% of the slot 138 is relatively constant (i.e., within 0.5 degrees). In more preferred embodiments, the wedge angle θW in at least the final 50% of the slot 138 is within the range of 4.25° to 4.75°. In still other preferred embodiments, the wedge angle θW in at least the final 40% of the slot 138 is about 4.5°.
As previously described, the outer housing 102 may be fixed to, and rotate with, the rotary of the snubbing jack or rig assist unit. The inner housing 104 may be partially or fully supported by radially spaced rollers 116, or by radially spaced groups 119 of rollers, which rollers may be, e.g., tapered rollers 116a, 116b or straight rollers 116c. Tapered rollers 116a, 116b may provide both vertical and radial support for the inner housing 104 within the outer housing, whereas straight sided rollers 116c may provide only radial support. In such case, horizontal bearings 129, which may be, e.g., UHMW polyethylene or hardened steel surfaces, may be provided for vertical support of the inner housing 104 within the outer housing 102. In this context, radial support of the inner housing 104 refers to providing radially-inward directed force to maintain the inner housing centered within the outer housing 102, and also to providing radially-inward directed force to resist deformation of the inner housing structure when the clamp is activated to grip a pipe. The linear actuators 114 couple the outer housing 102 and inner housing 104 and rotate the inner housing about the clamp center axis 109 with respect to the outer housing. The carriers 106 are held tangentially relative to the outer housing 102 by locating blocks (carrier guides) 122 forming tracks/slots 124. The carrier pin 130 on each carrier 106 projects into the actuator slots 138 on the inner housing 104.
Referring now to
During the opening (i.e., unclamping) stroke, the direction of movement of the actuators 114 is reversed and the inner housing 104 is rotated back to its original position relative to the outer housing 102, so that the carrier pins 130 follow the actuator slots 138 from the CLOSE end 142 toward the OPEN end 140. The carriers 106 (and the inserts 108, if provided) initially reduce the clamping force on the drill pipe 112, then move out of contact.
It will be appreciated that the powered milling clamp 100 can be sized according to the customer's specification to accommodate (i.e., work effectively with) multiple drill pipe/casing diameters and torque ratings. Further, it will be appreciated that, when the carriers 106 are configured to use removable power tong inserts or pipe inserts 108, a single powered milling clamp 100 may be selectively re-sized to accommodate pipes of various different sizes within a preselected range of sizes by selectively installing different pipe inserts designed for different pipe diameters within the preselected range. Further still, the linear actuators 114 may by hydraulically-, pneumatically- or electrically-powered as desired. The powered milling clamp 100 is more efficient, safer and more reliable than the existing manual milling clamps.
Although the preferred embodiment has been described in detail, it should be understood that various changes, substitutions and alterations can be made therein without departing from the spirit and scope of the invention as defined by the appended claims.
This application claims benefit of U.S. Provisional Application No. 61/950,505, filed Mar. 10, 2014, entitled POWERED MILLING CLAMP FOR DRILL PIPE, the specification of which is incorporated by reference herein in its entirety.
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